CN211821068U

CN211821068U - Electromechanical engineering is with a gallows of combatting earthquake

Info

Publication number: CN211821068U
Application number: CN202020301107.0U
Authority: CN
Inventors: 郑燕萍
Original assignee: Nanjing Uman New Energy Co ltd
Current assignee: Nanjing Uman New Energy Co ltd
Priority date: 2020-03-12
Filing date: 2020-03-12
Publication date: 2020-10-30
Anticipated expiration: 2030-03-12

Abstract

The utility model discloses an electromechanical engineering is with a antidetonation gallows, including cable, gallows body, spliced pole and lift post, the bottom of lift post is provided with the spliced pole, the bottom of spliced pole is provided with the gallows body, the inside of gallows body is provided with the cable, the both sides of gallows body all are provided with dismantlement structure, the both sides of lift bottom of the post all are provided with shock-absorbing structure. The utility model discloses a setting up the slider in the spout the inside, realized that the slider can be in spout the inside horizontal slip, be connected with the screw rod through the slider, then the screw rod is connected with the handle, when needs go up and down to whole equipment, rotatory handle has earlier realized that the handle drives the screw rod and removes to control having driven the slider, and the slider is connected with the shock-absorbing bar, and the shock-absorbing bar is connected with the lift post again, when the slider carries out horizontal slip, thereby has driven the lift post and has gone up and down.

Description

Electromechanical engineering is with a gallows of combatting earthquake

Technical Field

The utility model relates to an electromechanical engineering technical field specifically is an electromechanical engineering is with a gallows of combatting earthquake.

Background

An anti-seismic support and hanger for electromechanical engineering is an anti-seismic support which is used in the field of electromechanical engineering, and because most of pipelines and cables are laid on the top of a building when the pipelines and the cables are laid in the city at present, a support is needed to install and fix the pipelines and the cables.

In the process of implementing the present invention, the inventor finds that at least the following problems exist in the prior art and are not solved:

(1) the traditional anti-seismic support and hanger for electromechanical engineering is inconvenient for lifting the whole device in the using process;

(2) the traditional anti-seismic support and hanger for electromechanical engineering is inconvenient to damp the whole device in the using process, so that the safety of the whole device is prevented;

(3) traditional antidetonation gallows for electromechanical engineering is inconvenient dismantles whole device at the in-process that uses for it is very inconvenient to install the cable and maintain the cable.

SUMMERY OF THE UTILITY MODEL

An object of the utility model is to provide an electromechanical engineering is with a gallows of combatting earthquake to provide inconvenient lift, inconvenient shock attenuation and the inconvenient problem of dismantling in solving above-mentioned background art.

In order to achieve the above object, the utility model provides a following technical scheme: the utility model provides an electromechanical engineering is with a antidetonation gallows, includes cable, gallows body, spliced pole and lift post, the bottom of lift post is provided with the spliced pole, the bottom of spliced pole is provided with the gallows body, the inside of gallows body is provided with the cable, the both sides of gallows body all are provided with dismantlement structure, the both sides of lift toe end all are provided with shock-absorbing structure, shock-absorbing structure's top is provided with elevation structure.

Preferably, slider, spout, screw rod and handle have set gradually in elevation structure's inside, the inside both sides of spout all are provided with the screw rod, one side of screw rod is provided with the handle.

Preferably, the other side of the screw rod is provided with a sliding block, the inner diameter of the sliding groove is larger than the outer diameter of the sliding block, and a sliding structure is formed between the sliding groove and the sliding block.

Preferably, the inside of shock-absorbing structure has set gradually first spring, shock attenuation pole and telescopic link, the inside top of shock attenuation pole is provided with first spring.

Preferably, the bottom end of the first spring is provided with telescopic rods, and the telescopic rods are symmetrically distributed.

Preferably, the inside of dismantling the structure has set gradually dead lever, draw-in groove, fixture block, connecting rod, second spring and connecting block, the both ends of the inside of connecting block all are provided with the connecting rod, one side on connecting rod top all is provided with the dead lever, the bottom of dead lever is provided with the draw-in groove.

Preferably, a clamping block is arranged in the clamping groove, and a clamping structure is formed between the clamping groove and the clamping block.

Compared with the prior art, the beneficial effects of the utility model are that: the anti-seismic support and hanger for the electromechanical engineering not only realizes convenient lifting and shock absorption, but also realizes convenient disassembly;

(1) the sliding block is arranged in the sliding groove, so that the sliding block can slide left and right in the sliding groove, the sliding block is connected with the screw rod through the sliding block, then the screw rod is connected with the handle, when the whole device is required to be lifted, the handle is firstly rotated, the handle drives the screw rod to move, the sliding block is driven to move left and right, the sliding block is connected with the damping rod, the damping rod is connected with the lifting column, and when the sliding block slides left and right, the lifting column is driven to lift;

(2) the telescopic rod is connected with the first spring, so that the telescopic rod can move up and down to absorb shock under the action of the elastic force of the first spring when an earthquake occurs or external impact is applied, and the effect of shock absorption protection on the whole equipment is realized;

(3) through setting up the fixture block on the dead lever, the fixture block card has realized fixed to whole device in the draw-in groove the inside, when needs are dismantled, is connected with the connecting rod through the dead lever, then the connecting rod is connected with the second spring of connecting block the inside, according to the effect of second spring elasticity, when outside pulling dead lever, the second spring stretches out and draws back, has realized that the fixture block breaks away from the draw-in groove, has played the effect of dismantling.

Drawings

Fig. 1 is a schematic front view of a cross-sectional structure of the present invention;

FIG. 2 is a schematic view of the elevation structure of the present invention;

fig. 3 is an enlarged partial sectional view of the utility model at a in fig. 1;

fig. 4 is a schematic view of the shock-absorbing structure of the present invention.

In the figure: 1. a lifting structure; 101. a slider; 102. a chute; 103. a screw; 104. a handle; 2. a shock-absorbing structure; 201. a first spring; 202. a shock-absorbing lever; 203. a telescopic rod; 3. disassembling the structure; 301. fixing the rod; 302. a card slot; 303. a clamping block; 304. a connecting rod; 305. a second spring; 306. connecting blocks; 4. a cable; 5. a hanger body; 6. connecting columns; 7. and (4) lifting the column.

Detailed Description

The technical solutions in the embodiments of the present invention will be described clearly and completely with reference to the accompanying drawings in the embodiments of the present invention, and it is obvious that the described embodiments are only some embodiments of the present invention, not all embodiments. Based on the embodiments in the present invention, all other embodiments obtained by a person skilled in the art without creative work belong to the protection scope of the present invention.

Referring to fig. 1-4, the present invention provides an embodiment: an anti-seismic support and hanger for electromechanical engineering comprises a cable 4, a hanger body 5, a connecting column 6 and a lifting column 7, wherein the connecting column 6 is arranged at the bottom end of the lifting column 7, the hanger body 5 is arranged at the bottom end of the connecting column 6, the cable 4 is arranged inside the hanger body 5, dismounting structures 3 are arranged on two sides of the hanger body 5, damping structures 2 are arranged on two sides of the bottom end of the lifting column 7, and the lifting structure 1 is arranged at the top end of the damping structure 2;

the inside of the lifting structure 1 is sequentially provided with a sliding block 101, a sliding groove 102, a screw 103 and a handle 104, the two sides inside the sliding groove 102 are respectively provided with the screw 103, one side of the screw 103 is provided with the handle 104, the other side of the screw 103 is provided with the sliding block 101, the inner diameter of the sliding groove 102 is larger than the outer diameter of the sliding block 101, and a sliding structure is formed between the sliding groove 102 and the sliding block 101;

specifically, as shown in fig. 1 and fig. 2, when the mechanism is used, firstly, the slider 101 arranged in the sliding groove 102 is used to realize that the slider 101 can slide left and right in the sliding groove 102, the slider 101 is connected with the screw 103, then the screw 103 is connected with the handle 104, when the whole device needs to be lifted, the handle 104 is rotated first, so that the handle 104 drives the screw 103 to move, thereby driving the slider 101 to move left and right, the slider 101 is connected with the shock absorption rod 202, the shock absorption rod 202 is connected with the lifting column 7, and when the slider 101 slides left and right, the lifting column 7 is driven to lift;

a first spring 201, a shock absorption rod 202 and an expansion rod 203 are sequentially arranged in the shock absorption structure 2, the first spring 201 is arranged at the top end of the interior of the shock absorption rod 202, the expansion rod 203 is arranged at the bottom end of the first spring 201, and the expansion rods 203 are symmetrically distributed;

specifically, as shown in fig. 1 and 4, when the mechanism is used, firstly, the telescopic rod 203 arranged in the shock absorption rod 202 can move in the shock absorption rod 202, and the telescopic rod 203 is connected with the first spring 201, so that when an earthquake occurs or external impact is received, the telescopic rod 203 can move up and down to absorb shock according to the elastic force of the first spring 201, and the effect of shock absorption and protection on the whole equipment is achieved;

the fixing rod 301, the clamping groove 302, the clamping block 303, the connecting rod 304, the second spring 305 and the connecting block 306 are sequentially arranged in the dismounting structure 3, the connecting rod 304 is arranged at each of two ends of the inside of the connecting block 306, the fixing rod 301 is arranged on one side of the top end of the connecting rod 304, the clamping groove 302 is arranged at the bottom end of the fixing rod 301, the clamping block 303 is arranged in the clamping groove 302, and a clamping structure is formed between the clamping groove 302 and the clamping block 303;

specifically, as shown in fig. 1 and fig. 2, when the mechanism is used, firstly, the fixture block 303 is clamped in the clamping groove 302 through the fixture block 303 arranged on the fixing rod 301, so that the fixing of the whole device is realized, when the mechanism needs to be disassembled, the fixing rod 301 is connected with the connecting rod 304 through the fixing rod 301, then the connecting rod 304 is connected with the second spring 305 in the connecting block 306, and according to the action of the elastic force of the second spring 305, when the fixing rod 301 is pulled outwards, the second spring 305 stretches and retracts, so that the fixture block 303 is separated from the clamping groove 302, and the disassembling effect is realized.

The working principle is as follows: the utility model discloses when using, at first, through setting up the slider 101 in spout 102 the inside, slider 101 has been realized and can be in spout 102 the inside horizontal slip, be connected with screw rod 103 through slider 101, then screw rod 103 is connected with handle 104, when needs go up and down to whole equipment, rotatory handle 104 earlier, it drives screw rod 103 removal to have realized handle 104, thereby it controls to have driven slider 101 and remove, and slider 101 is connected with shock absorber rod 202, shock absorber rod 202 is connected with lift post 7 again, when slider 101 carries out horizontal slip, thereby it goes up and down to have driven lift post 7.

Afterwards, through setting up the telescopic link 203 in shock attenuation pole 202 the inside, realized that telescopic link 203 can remove in shock attenuation pole 202 the inside, be connected with first spring 201 through telescopic link 203, when meetting the earthquake or receiving external impact, according to the effect of first spring 201 elasticity for telescopic link 203 can reciprocate the shock attenuation, thereby has realized the effect to whole equipment shock attenuation protection.

Finally, through the fixture block 303 arranged on the fixing rod 301, the fixture block 303 is clamped in the clamping groove 302, so that the whole device is fixed, when the device needs to be disassembled, the device is connected with the connecting rod 304 through the fixing rod 301, then the connecting rod 304 is connected with the second spring 305 in the connecting block 306, under the action of the elastic force of the second spring 305, when the fixing rod 301 is pulled outwards, the second spring 305 stretches and retracts, the fixture block 303 is separated from the clamping groove 302, and the disassembling effect is achieved.

It is obvious to a person skilled in the art that the invention is not restricted to details of the above-described exemplary embodiments, but that it can be implemented in other specific forms without departing from the spirit or essential characteristics of the invention. The present embodiments are therefore to be considered in all respects as illustrative and not restrictive, the scope of the invention being indicated by the appended claims rather than by the foregoing description, and all changes which come within the meaning and range of equivalency of the claims are therefore intended to be embraced therein. Any reference sign in a claim should not be construed as limiting the claim concerned.

Claims

1. The utility model provides an electromechanical engineering is with a antidetonation gallows, includes cable (4), gallows body (5), spliced pole (6) and lift post (7), its characterized in that: the bottom of lift post (7) is provided with spliced pole (6), the bottom of spliced pole (6) is provided with gallows body (5), the inside of gallows body (5) is provided with cable (4), the both sides of gallows body (5) all are provided with dismantlement structure (3), the both sides of lift post (7) bottom all are provided with shock-absorbing structure (2), the top of shock-absorbing structure (2) is provided with elevation structure (1).

2. An anti-seismic support and hanger for electromechanical engineering according to claim 1, wherein: the lifting mechanism is characterized in that a sliding block (101), a sliding groove (102), a screw rod (103) and a handle (104) are sequentially arranged in the lifting structure (1), the screw rod (103) is arranged on two sides of the inside of the sliding groove (102), and the handle (104) is arranged on one side of the screw rod (103).

3. An anti-seismic support and hanger for electromechanical engineering according to claim 2, wherein: the other side of the screw rod (103) is provided with a sliding block (101), the inner diameter of the sliding groove (102) is larger than the outer diameter of the sliding block (101), and a sliding structure is formed between the sliding groove (102) and the sliding block (101).

4. An anti-seismic support and hanger for electromechanical engineering according to claim 1, wherein: the damping structure is characterized in that a first spring (201), a damping rod (202) and a telescopic rod (203) are sequentially arranged inside the damping structure (2), and the first spring (201) is arranged on the top end inside the damping rod (202).

5. An anti-seismic support and hanger for electromechanical engineering according to claim 4, wherein: the bottom end of the first spring (201) is provided with telescopic rods (203), and the telescopic rods (203) are symmetrically distributed.

6. An anti-seismic support and hanger for electromechanical engineering according to claim 1, wherein: the detachable structure is characterized in that a fixing rod (301), a clamping groove (302), a clamping block (303), a connecting rod (304), a second spring (305) and a connecting block (306) are sequentially arranged inside the detachable structure (3), the connecting rod (304) is arranged at each of two ends of the inside of the connecting block (306), the fixing rod (301) is arranged on one side of the top end of the connecting rod (304), and the clamping groove (302) is arranged at the bottom end of the fixing rod (301).

7. An anti-seismic support and hanger for electromechanical engineering according to claim 6, wherein: a clamping block (303) is arranged in the clamping groove (302), and a clamping structure is formed between the clamping groove (302) and the clamping block (303).